Neurobiological Principles Applied to the Rehabilitation of Stroke Patients

This study has been completed.

Sponsor:

Emory University

ClinicalTrials.gov Identifier:

NCT00715520

First Posted: July 15, 2008

Last Update Posted: October 16, 2017

The safety and scientific validity of this study is the responsibility of the study sponsor and investigators. Listing a study does not mean it has been evaluated by the U.S. Federal Government.
Read our disclaimer for details.

Motor evoked potential (MEP) amplitudes were measured prior to treatment (baseline), immediately after the treatment (post-training 1), 30 minutes after the treatment (post-training 2), and 60 minutes after the treatment (post-training 3).The MEP is elicited by transcranial magnetic stimulation (TMS) at increased intensity. Its amplitude is measured from peak to peak and expressed in millivolts (mV). Measured MEP amplitudes were plotted against the intensity to create a stimulus response curve (SRC). SRCs were modeled by a 3- parameter sigmoid function and MEPmax was extracted. Long-lasting increases in MEP amplitude indicate increases in motor cortex excitability and are associated with motor learning.

Mean peak acceleration was measured across study drug conditions prior to treatment (baseline), immediately after the treatment (post-training 1), 30 minutes after the treatment (post-training 2) and 60 minutes after the treatment (post-training 3). Increases in the mean peak acceleration of the trained wrist extension movements indicate motor learning. Acceleration was measured in g; a symbol for the average acceleration produced by gravity at the Earth's surface.

Mean sum of normalized MEP for repeated TMS (rTMS) conditions with respect to the pulse (-100, +300, placebo, zero) prior to treatment (baseline), immediately after the treatment (post-training 1), 30 minutes after the treatment (post-training 2) and 60 minutes after the treatment (post-training 3). Its amplitude is measured from peak to peak and expressed in mV. Long- lasting increases in MEP amplitude indicate increases in motor cortex excitability and are associated with motor learning.

Mean peak acceleration of wrist movements for repeated TMS (rTMS) conditions with respect of the TMS pulse (-100, +300, placebo, zero) prior to treatment (baseline), immediately after the treatment (post-training 1), 30 minutes after the treatment (post-training 2) and 60 minutes after the treatment (post-training 3). Increases in the mean peak acceleration of the trained wrist extension movements indicate motor learning. Acceleration was measured in g; a symbol for the average acceleration produced by gravity at the Earth's surface.

Mean peak acceleration for the different frequencies of rTMS treatment (placebo, 0.1 Hz, 0.25 Hz, 0.5 Hz) prior to treatment (baseline), immediately after the treatment (post-training 1), 30 minutes after the treatment (post-training 2) and 60 minutes after the treatment (post-training 3). Increases in the mean peak acceleration of the trained wrist extension movements indicate motor learning. Acceleration was measured in g; a symbol for the average acceleration produced by gravity at the Earth's surface.

Motor evoked potential (MEP) amplitudes were measured prior to treatment (baseline), immediately after the treatment (post-training 1), 30 minutes after the treatment (post-training 2), and 60 minutes after the treatment (post-training 3).The MEP is elicited by transcranial magnetic stimulation (TMS) at increased intensity. Its amplitude is measured from peak to peak and expressed in millivolts (mV). Measured MEP amplitudes were plotted against the intensity to create a stimulus response curve (SRC). SRCs were modeled by a 3- parameter sigmoid function and MEPmax was extracted. Long-lasting increases in MEP amplitude indicate increases in motor cortex excitability and are associated with motor learning.

Mean peak acceleration was measured across study drug conditions prior to treatment (baseline), immediately after the treatment (post-training 1), 30 minutes after the treatment (post-training 2) and 60 minutes after the treatment (post-training 3). Increases in the mean peak acceleration of the trained wrist extension movements indicate motor learning. Acceleration was measured in g; a symbol for the average acceleration produced by gravity at the Earth's surface.

Original Secondary Outcome Measures ICMJE

Not Provided

Current Other Outcome Measures ICMJE

Not Provided

Original Other Outcome Measures ICMJE

Not Provided

Descriptive Information

Brief Title ICMJE

Neurobiological Principles Applied to the Rehabilitation of Stroke Patients

Official Title ICMJE

Neurobiological Principles Applied to the Rehabilitation of Stroke Patients

Brief Summary

The purpose of this study is to use (Transcranial Magnetic Stimulation) TMS or drugs to improve learning of movement skills and the adaptation processes in patients after stroke. Once investigators have determined the improving effect of TMS and the drugs on learning of movement skills, the study team may be able to provide information that improves rehabilitative treatment and helps to improve recovery after stroke.

Detailed Description

Previous studies have shown, that when patients learn a new motor movement, it may cause a change in the way the nerves act in the area of the brain that controls movement. This change is called use-dependent plasticity. The ability of that part of the brain, called the motor cortex (M1), to reorganize plays a major role in the recovery of motor deficits post-stroke; hence the importance for further development of rehabilitative strategies that utilize this potential for recovery. In this proposed study, investigators will further examine influences of use-dependent plasticity in the non-injured M1 of healthy subjects and injured M1 of stroke subjects using a combination of non-invasive cortical stimulation, medication, and exercise techniques. In Aim 1, investigators will test the effect of drugs that interact specifically with different neurotransmitter systems on use-dependent plasticity in intact M1 of healthy humans. In Aim 2, investigators will identify the parameters for non-invasive transcranial magnetic stimulation (TMS) of M1 that are most effective to enhance use-dependent plasticity in intact healthy human M1. In Aim 3, investigators will test the drugs and rTMS protocols that were demonstrated to be most effective to enhance use- dependent plasticity in the Specific Aim 1 and 2 and apply them to participants who have experienced a stroke. Results from this study will help to inform future research about the efficacy of plasticity enhancing methods in injured M1 of stroke patients.

Each TMS training session will begin with a baseline measurement lasting about 30 minutes in which brief magnetic pulses will be generated by the single—pulse and paired pulse TMS stimulator and the responses are recorded with surface EMG electrodes. Participants will be instructed to move their wrist for up to ½ hour. After these measures, rTMS will be applied to the scalp during training. Stimulation will occur at a low rate of different frequencies and different times with respect to the training movement depending on the experimental condition. In the last phase of the session post—training measurements will be done using single TMS pulses. TMS pulses and intensity with be given in random order.

The order in which Placebo is given will be randomized per participant.

Other: Sham Transcranial Magnetic Stimulation (TMS)

Sham TMS pulses will be randomly administered during TMS sessions.

Other: Transcranial Magnetic Stimulation (TMS) Training

TMS surface electromyographic activity will be recorded with surface electrodes mounted on the skin overlaying a forearm muscle. Single pulses of TMS at increasing intensity will be delivered to measure motor cortex excitability. Peak acceleration and TMS evoked responses in the muscle will be measured prior to the training, after completion of the training and again one hour after completion of the training.

Cerebral ischemic infarction more than 6 months prior to entering the study

Single lesion as defined by MRI of the brain affecting the primary motor output system of the hand at a cortical (M1) level or subcortical level, or unilateral, and supratentorial in absence of history of a previous symptomatic stroke within 3 months of the current stroke

Dense paresis of the hand for more than three days after cerebral infarction (MRC of < 4- of wrist- and finger extension/flexion movements)

Good functional recovery of hand function as defined by MRC of 4 or 4+ of wrist- and finger extension/flexion movements

Ability to perform wrist extension movements

Ability to meet criteria of inclusion experiment

Ability to give informed consent

Ability of TMS to elicit a measurable MEP of > 100 μV and an increase in MEP amplitude with increasing stimulus intensity (up to 100% of MSO) of at least 20% over MEP amplitude at MT

Exclusion Criteria:

History or neurological or psychiatric disease, including bipolar disorder

Intake of CNS active drugs

History of seizure disorder

History of migraine headaches

History of anaphylaxis or allergic reactions

Contraindication to TMS

Sex/Gender

Sexes Eligible for Study:

All

Ages

18 Years to 80 Years (Adult, Senior)

Accepts Healthy Volunteers

Yes

Contacts ICMJE

Contact information is only displayed when the study is recruiting subjects